Lower time bounds for solving linear diophantine equations on several parallel computational models

Q4 Mathematics 信息与控制 Pub Date : 1985-10-01 DOI:10.1016/S0019-9958(85)80035-8

Friedhelm Meyer auf der Heide

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引用次数: 3

Abstract

We consider parallel random access machines (PRAM's) with p processors and distributed systems of random access machines (DRAM's) with p processors being partially joint by wires according to a communication graph. For these computational models we prove lower bounds for testing the solvability of linear Diophantine equations and related problems including the knapsack problem. These bounds are achieved by generalizing and simplifying a lower bound for parallel computation trees due to Yao, introducing a new type of computation trees which models computations of DRAM's, and by generalizing a technique used by Paul and Simon and Klein and Meyer auf der Heide to carry over lower bounds from computation trees to RAM's. Thereby we prove that for many problems, p processors cannot speed up a computation by a factor O(p) but only by a factor O(log(p + 1)) and in the case of DRAM's whose communication network has degree c by a factor O(log(c + 1)) only.

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求解若干并行计算模型上的线性丢番图方程的下时限

考虑具有p个处理器的并行随机存取机(PRAM)和具有p个处理器的分布式随机存取机(DRAM)系统根据通信图通过导线部分连接。对于这些计算模型，我们证明了测试线性丢芬图方程和相关问题(包括背包问题)可解性的下界。这些边界是通过推广和简化并行计算树的下界来实现的，因为Yao引入了一种新型的计算树来模拟DRAM的计算，并通过推广Paul, Simon, Klein和Meyer auf der Heide使用的技术来将下界从计算树转移到RAM。因此，我们证明了对于许多问题，p处理器不能以一个因子O(p)加速计算，而只能以一个因子O(log(p + 1))加速计算，并且在通信网络具有c度的DRAM的情况下，只能以一个因子O(log(c + 1))加速计算。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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